4. Television
  5. Camera, system and detail
  6. Combined image signal generator and general image signal...

Exposure control circuit for solid-state imaging apparatus

Television – Camera – system and detail – Combined image signal generator and general image signal...

Reexamination Certificate

Rate now
  [ 0.00 ] – not rated yet Voters 0   Comments 0

Details

C348S223100, C348S362000, C358S516000

Reexamination Certificate

active

06768511

ABSTRACT:

BACKGROUND OF THE INVENTION
The present invention relates to a solid-state imaging apparatus, and more particularly, to a solid-state imaging apparatus that performs exposure control and white balance control.
FIG. 1
is a block diagram showing the configuration of a conventional imaging apparatus
100
which uses a CCD image sensor, or CCD
1
.
The CCD
1
, which is a solid-state imaging device, has a plurality of light-receiving pixels, a plurality of vertical shift registers, and usually a horizontal shift register. The light-receiving pixels are arranged in a matrix form on a light-receiving surface at regular intervals and produce and store information charges corresponding to the image of a sensed object. The vertical shift registers are arranged to correspond to the columns of the light-receiving pixels and sequentially shift the information charges stored in the light-receiving pixels in the vertical direction. The horizontal shift register is arranged on the output side of the vertical shift registers and receives the information charges output from the vertical shift registers, and then transfers the information charges row by row. This allows the horizontal shift register to output an image signal A
1
in accordance with the information charges stored in the light-receiving pixels.
When performing color image sensing, a color filter for color distribution is attached to the light-receiving surface in order to associate the individual light-receiving pixels of the CCD
1
with predetermined color components. There are stripe type and mosaic type color filters. Although the structure of the mosaic type color filter is more complicated than the stripe type color filter, the mosaic type filter has higher horizontal resolution. Thus, imaging apparatuses that require high resolution, such as a video camera, use mosaic type color filters.
A drive circuit
2
responds to various timing signals from a timing control circuit
3
and supplies a multi-phase drive clock to the shift registers of the CCD
1
. For example, a 4-phase vertical transfer clock &PHgr;v is supplied to the vertical shift registers, and a 2-phase horizontal transfer clock &PHgr;h is supplied to the horizontal shift register. In accordance with a reference clock having a predetermined cycle, the timing control circuit
3
produces a vertical timing signal VD, which determines the vertical scan timing of the CCD
1
, and a horizontal timing signal HD, which determines the horizontal scan timing, and supplies the timing signals to the drive circuit
2
.
An analog processing circuit
4
performs a process, such as sampling and holding or level clamping, on the image signal A
1
received from the CCD
1
to produce an image signal A
2
which conforms to a predetermined format. For example, in the sample and hold process, only signal levels are extracted from the image signal A
1
, which has reset levels and signal levels alternately repeated in synchronism with the output operation of the CCD
1
. In the level clamping process, a black reference level set at the end of the horizontal scanning period of the image signal A
1
is clamped to a predetermined level every horizontal scanning period. An A/D converter circuit
5
quantizes the image signal A
2
received from the analog processing circuit
4
to generate image data D
3
, which represents the information corresponding to each light-receiving pixel of the CCD
1
with a digital value.
A color computation circuit
6
receives the image data D
3
from the A/D converter circuit
5
, separates the data D
3
into three color components, and generates color component data. The color computation circuit
6
further generates color data C
4
corresponding to the three primary colors (R: red, G: green and B: blue) of light. For example, if the color filter has yellow (YE), cyan (Cy), green (G), and white (W) segments, the color component data C[Ye], C[Cy], C[G], and C[W] undergo color computation processes in accordance with the equations listed below to generate color data C
4
, which corresponds to the three primary colors of light.
Ye−G=R
Cy−G=B
G=G
A white balance circuit
7
assigns specific gains to each of the color components in order to adjust the balance of each color component and generate adjusted color data C
5
. In other words, the white balance circuit
7
compensates for differences in the sensitivities of the light-receiving pixels of the CCD
1
that depend on each color component and individually sets the gain of each color component to improve the color reproduction of a reproduced image.
A color difference computation circuit
8
performs a computation process on the adjusted color data C
5
received from the white balance circuit
7
and generates color difference data U and V. The color difference computation circuit
8
combines the R, G, and B components of the adjusted color data at a ratio of 3:6:1 to generate luminance data. Then, the color difference computation circuit
8
subtracts the luminance data from the B component to generate the color difference data U, and the luminance data from the R component to generate the color difference data V.
A luminance computation circuit
9
combines the plurality of color components (in this case, four) included in the image data D
3
to generate luminance data B
4
. That is, if the components Ye, Cy, G, W are combined, the following equation is obtained.
Ye
+
Cy
+
G
+
W
=
(
B
+
G
)
+
(
R
+
G
)
+
G
+
(
R
+
G
+
B
)
=
2

R
+
4

G
+
2

B
This generates luminance data in which the R, G and B components are combined at a ratio of 1:2:1. While the NTSC standards define a luminance signal produced by combining the R, G and B components at a ratio of 3:6:1, a luminance signal produced by combining the components at a ratio close to this ratio does not cause a practical problem.
An outline correction circuit
10
emphasizes a specific frequency component included in the luminance data B
4
to generate aperture data and adds the aperture data to the luminance data B
4
. In other words, to emphasize the image outline of a sensed object, the outline correction circuit
10
performs a filtering process on the luminance data B
4
to emphasize a frequency component that is one fourth the sampling frequency of the image signal D
3
output by the A/D converter circuit
5
and generate the aperture data. The luminance data B
4
generated by adding the aperture data is provided as luminance data Y to an external display device or recording device together with the color difference data U and V.
The solid-state imaging apparatus
100
determines the exposure state based on the level of the image signal and feeds back the determination result to the timing control circuit
3
. The timing control circuit
3
decreases and lengthens the exposure time of the CCD
1
based on the determination result to obtain an appropriate exposure time. The exposure time of the CCD
1
is the period between when the storing of the information charges starts to when the transmission of the information charges starts. Therefore, an appropriate amount of information charges may be stored in each light-receiving pixel by changing the time point for starting the storing of the information charges. Further, the gain of each color component is determined based on the average level of the image signal, and the determined gain is applied to the color component to perform white balance control.
During exposure control of the CCD
1
, the exposure state is determined during each vertical scan period, and the exposure time of the CCD
1
, or the shutter timing, is updated every vertical scan period. This enables the CCD
1
to follow changes in the luminance of the sensed object. In comparison, during white balance control, the color balance of the sensed object changes more gradually than the luminance of the sensed object. Thus, the gain set for each color component is updated in cycles that are longer than that of the exposure control.
When the imaging app

Nakai Tomomichi

Inventor

  [ 0.00 ] – not rated yet Voters 0   Comments 0

Nakakuki Toshio

Inventor

  [ 0.00 ] – not rated yet Voters 0   Comments 0

Garber Wendy R.

Examiner

  [ 0.00 ] – not rated yet Voters 0   Comments 0

Sanyo Electric Co,. Ltd.

Corporate Assignee

  [ 0.00 ] – not rated yet Voters 0   Comments 0

Sheridan Ross PC

Law Firm

  [ 0.00 ] – not rated yet Voters 0   Comments 0

LandOfFree

Say what you really think

Search LandOfFree.com for the USA inventors and patents. Rate them and share your experience with other people.

Rating

Exposure control circuit for solid-state imaging apparatus does not yet have a rating. At this time, there are no reviews or comments for this patent.

If you have personal experience with Exposure control circuit for solid-state imaging apparatus, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Exposure control circuit for solid-state imaging apparatus will most certainly appreciate the feedback.

Rate now

     

Profile ID: LFUS-PAI-O-3211393

  Search
All data on this website is collected from public sources. Our data reflects the most accurate information available at the time of publication.

Canada

 Charities
 Companies
 MP Candidates
 Patents
 Employee Salary Disclosure

World

 Places of the World
 Scientific Papers

United States

 Banks
 Companies
 Counties
 Patents
 Employee Salary Disclosure